Detection of ultra-low protein concentrations with the simplest possible field effect transistor
Detection of ultra-low protein concentrations with the simplest possible field effect transistor
Silicon nanowire (Si NW) sensors have attracted great attention due to their ability to provide fast, low-cost, label-free, real-time detection of chemical and biological species. Usually configured as field effect transistors (FETs), they have already demonstrated remarkable sensitivity with high selectivity (through appropriate functionalisation) towards a large number of analytes in both liquid and gas phases. Despite these excellent results, Si NW FET sensors have not yet been successfully employed to detect single molecules of either a chemical or biological target species. Here we show that sensors based on silicon junctionless nanowire transistors (JNTs), the simplest possible transistors, are capable of detecting the protein streptavidin at a concentration as low as 580 zM closely approaching the single molecule level. This ultrahigh detection sensitivity is due to the intrinsic advantages of junctionless devices over conventional FETs. Apart from their superior functionality, JNTs are much easier to fabricate by standard microelectronic processes than transistors containing p–n junctions. The ability of JNT sensors to detect ultra-low concentrations (in the zeptomolar range) of target species, and their potential for low-cost mass production, will permit their deployment in numerous environments, including life sciences, biotechnology, medicine, pharmacology, product safety, environmental monitoring and security.
Georgiev, Yordan
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Petkov, Nikolay
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Yu, Ran
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Nightingale, Adrian
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Buitrago, Elizabeth
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Lotty, Olan
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de Mello, John C.
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M. Ionescu, Adrian
f798bd81-13bc-48d6-826b-a390735eda7b
Holmes, Justin D.
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8 May 2019
Georgiev, Yordan
d98273f7-3086-4159-883e-c0da58be2a4d
Petkov, Nikolay
4243e25a-7819-4fa7-afb4-30a86d8b96be
Yu, Ran
5249c244-62ef-4a65-8402-8c73155b9c48
Nightingale, Adrian
4b51311d-c6c3-40d5-a13f-ab8917031ab3
Buitrago, Elizabeth
c5db7e94-5459-449e-944d-b5f2fc69a399
Lotty, Olan
d415a0cc-bf3e-4142-ab33-febb0a7a4047
de Mello, John C.
4807193f-f95b-4c91-9cb9-f52df1efc9f4
M. Ionescu, Adrian
f798bd81-13bc-48d6-826b-a390735eda7b
Holmes, Justin D.
98f11a8f-7130-4074-8928-1fb7c66b05d4
Georgiev, Yordan, Petkov, Nikolay, Yu, Ran, Nightingale, Adrian, Buitrago, Elizabeth, Lotty, Olan, de Mello, John C., M. Ionescu, Adrian and Holmes, Justin D.
(2019)
Detection of ultra-low protein concentrations with the simplest possible field effect transistor.
Nanotechnology, 30 (324001), [324001].
(doi:10.1088/1361-6528/ab192c).
Abstract
Silicon nanowire (Si NW) sensors have attracted great attention due to their ability to provide fast, low-cost, label-free, real-time detection of chemical and biological species. Usually configured as field effect transistors (FETs), they have already demonstrated remarkable sensitivity with high selectivity (through appropriate functionalisation) towards a large number of analytes in both liquid and gas phases. Despite these excellent results, Si NW FET sensors have not yet been successfully employed to detect single molecules of either a chemical or biological target species. Here we show that sensors based on silicon junctionless nanowire transistors (JNTs), the simplest possible transistors, are capable of detecting the protein streptavidin at a concentration as low as 580 zM closely approaching the single molecule level. This ultrahigh detection sensitivity is due to the intrinsic advantages of junctionless devices over conventional FETs. Apart from their superior functionality, JNTs are much easier to fabricate by standard microelectronic processes than transistors containing p–n junctions. The ability of JNT sensors to detect ultra-low concentrations (in the zeptomolar range) of target species, and their potential for low-cost mass production, will permit their deployment in numerous environments, including life sciences, biotechnology, medicine, pharmacology, product safety, environmental monitoring and security.
Text
Nanotechnology_Georgiev et al_Second Revision_Clean
- Accepted Manuscript
More information
Accepted/In Press date: 15 April 2019
e-pub ahead of print date: 15 April 2019
Published date: 8 May 2019
Identifiers
Local EPrints ID: 430932
URI: http://eprints.soton.ac.uk/id/eprint/430932
ISSN: 0957-4484
PURE UUID: 7d850253-4aae-43d1-aa0d-e5940adaed05
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Date deposited: 17 May 2019 16:30
Last modified: 16 Mar 2024 07:50
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Contributors
Author:
Yordan Georgiev
Author:
Nikolay Petkov
Author:
Ran Yu
Author:
Elizabeth Buitrago
Author:
Olan Lotty
Author:
John C. de Mello
Author:
Adrian M. Ionescu
Author:
Justin D. Holmes
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